Introduce a NativeRegisterContextFreeBSD for 32-bit ARM platform.
This includes support for GPR + VFP registers as exposed by FreeBSD's
ptrace(2) API. Hardware breakpoints or watchpoints are not supported
due to missing kernel support. The code is roughly based on the arm64
context.
It also includes an override for GetSoftwareBreakpointTrapOpcode() based
on the matching code in the PlatformFreeBSD plugin.
Differential Revision: https://reviews.llvm.org/D95696
Introduce arm64 support in the FreeBSDRemote plugin. The code
is roughly based on Linux and reuses the same POSIX RegisterInfos
(but the buffers need to be a few bytes larger due to stricter struct
member alignment in FreeBSD structures -- luckily, they do not affect
the actual member offsets). It supports reading and writing
general-purpose and FPU registers. SVE and hardware watchpoint support
is missing due to the limitations of FreeBSD ptrace(2) API.
Differential Revision: https://reviews.llvm.org/D95297
Adds support for running a Lua function when a breakpoint is hit.
Example:
breakpoint command add -s lua -F abc
The above runs the Lua function 'abc' passing 2 arguments. 'frame', 'bp_loc' and 'extra_args'.
A third parameter 'extra_args' is only present when there is structured data
declared in the command line.
Example:
breakpoint command add -s lua -F abc -k foo -v bar
Differential Revision: https://reviews.llvm.org/D93649
Currently when LLDB has enough data in the debug information to import the `std` module,
it will just try to import it. However when debugging libraries where the sources aren't
available anymore, importing the module will generate a confusing diagnostic that
the module couldn't be built.
For the fallback mode (where we retry failed expressions with the loaded module), this
will cause the second expression to fail with a module built error instead of the
actual parsing issue in the user expression.
This patch adds checks that ensures that we at least have any source files in the found
include paths before we try to import the module. This prevents the module from being
loaded in the situation described above which means we don't emit the bogus 'can't
import module' diagnostic and also don't waste any time retrying the expression in the
fallback mode.
For the unit tests I did some refactoring as they now require a VFS with the files in it
and not just the paths. The Python test just builds a binary with a fake C++ module,
then deletes the module before debugging.
Fixes rdar://73264458
Reviewed By: JDevlieghere
Differential Revision: https://reviews.llvm.org/D95096
When a program maps one of its own modules for reading, and then
crashes, breakpad can emit two entries for that module in the
ModuleList. We have logic to identify this case by checking permissions
on mapped memory regions and report just the module with an executable
region. As currently written, though, the check is asymmetric -- the
entry with the executable region must be the second one encountered for
the preference to kick in.
This change makes the logic symmetric, so that the first-encountered
module will similarly be preferred if it has an executable region but
the second-encountered module does not. This happens for example when
the module in question is the executable itself, which breakpad likes to
report first -- we need to ignore the other entry for that module when
we see it later, even though it may be mapped at a lower virtual
address.
Reviewed By: clayborg
Differential Revision: https://reviews.llvm.org/D94629
This test seems to be broken there (which is not totally surprising as
this functionality was never used on windows). Disable the test while I
investigate.
- s/createUniqueFile/createUniquePath -- we don't want to create the file,
just the file name
- s/data()/str().c_str()/ -- paths given to system apis must be
null-terminated
To get LLDB one step closer to fulfil the software redundancy requirements of
modern aircrafts, we apparently decided to have two separately maintained
implementations of `CreateTypedef` in TypeSystemClang. Let's pass on the idea of
an LLDB-powered jetliner and deleted one implementation.
On a more serious note: This function got duplicated a long time ago when the
idea of CompilerType with a backing TypeSystemClang subclass happened
(56939cb310). One implementation was supposed to
be called from CompilerType::CreateTypedef and the other has just always been
around to create typedefs. By accident one of the implementations is only used
by the PDB parser while the CompilerType::CreateTypedef backend is used by the
rest of LLDB.
We also had some patches over the year that only fixed one of the two functions
(D18099 for example only fixed up the CompilerType::CreateTypedef
implementation). D51162 and D86140 both fixed the same missing `addDecl` call
for one of the two implementations.
This patch:
* deletes the `CreateTypedefType` function as its only used by the PDB parser
and the `CreateTypedef` implementation is anyway needed as it's the backend
implementation of CompilerType.
* replaces the calls in the PDB parser by just calling the CompilerType wrapper.
* moves the documentation to the remaining function.
* moves the check for empty typedef names that was only in the deleted
implementation to the other (I don't think this fixes anything as I believe
all callers are already doing the same check).
I'll fix up the usual stuff (not using StringRef, not doing early exit) in a NFC
follow-up.
This patch is not NFC as the PDB parser now calls the function that has the fix
from D18099.
Reviewed By: labath, JDevlieghere
Differential Revision: https://reviews.llvm.org/D93382
TargetList::CreateTarget automatically adds created target to the list, however,
CommandObjectTargetCreate does some additional preparation after creating a target
and which can fail. The command should remove created target if it failed. Since
the function has many ways to return, scope guard does this work safely.
Changes to the TargetList make target adding and selection more transparent.
Other changes remove unnecessary SetSelectedTarget after CreateTarget.
Differential Revision: https://reviews.llvm.org/D93052
Right now we have one large AST for all types in LLDB. All ODR violations in
types we reconstruct are resolved by just letting the ASTImporter handle the
conflicts (either by merging types or somehow trying to introduce a duplicated
declaration in the AST). This works ok for the normal types we build from debug
information as most of them are just simple CXXRecordDecls or empty template
declarations.
However, with a loaded `std` C++ module we have alternative versions of pretty
much all declarations in the `std` namespace that are much more fleshed out than
the debug information declarations. They have all the information that is lost
when converting to DWARF, such as default arguments, template default arguments,
the actual uninstantiated template declarations and so on.
When we merge these C++ module types into the big scratch AST (that might
already contain debug information types) we give the ASTImporter the tricky task
of somehow creating a consistent AST out of all these declarations. Usually this
ends in a messy AST that contains a mostly broken mix of both module and debug
info declarations. The ASTImporter in LLDB is also importing types with the
MinimalImport setting, which usually means the only information we have when
merging two types is often just the name of the declaration and the information
that it contains some child declarations. This makes it pretty much impossible
to even implement a better merging logic (as the names of C++ module
declarations and debug info declarations are identical).
This patch works around this whole merging problem by separating C++ module
types from debug information types. This is done by splitting up the single
scratch AST into two: One default AST for debug information and a dedicated AST
for C++ module types.
The C++ module AST is implemented as a 'specialised AST' that lives within the
default ScratchTypeSystemClang. When we select the scratch AST we can explicitly
request that we want such a isolated sub-AST of the scratch AST. I kept the
infrastructure more general as we probably can use the same mechanism for other
features that introduce conflicting types (such as programs that are compiled
with a custom -wchar-size= option).
There are just two places where we explicitly have request the C++ module AST:
When we export persistent declarations (`$mytype`) and when we create our
persistent result variable (`$0`, `$1`, ...). There are a few formatters that
were previously assuming that there is only one scratch AST which I cleaned up
in a preparation revision here (D92757).
Reviewed By: aprantl
Differential Revision: https://reviews.llvm.org/D92759
Prevent lldb from crashing when multiple threads are concurrently
accessing the SB API with reproducer capture enabled.
The API instrumentation records both the input arguments and the return
value, but it cannot block for the duration of the API call. Therefore
we introduce a sequence number that allows to to correlate the function
with its result and add locking to ensure those two parts are emitted
atomically.
Using the sequence number, we can detect situations where the return
value does not succeed the function call, in which case we print an
error saying that concurrency is not (currently) supported. In the
future we might attempt to be smarter and read ahead until we've found
the return value matching the current call.
Differential revision: https://reviews.llvm.org/D92820
Extract remote debugging logic from PlatformMacOSX and move it into
PlatformRemoteMacOSX so it can benefit from all the logic necessary for
remote debugging.
Until now, remote macOS debugging was treated almost identical to local
macOS debugging. By moving in into its own class, we can have it inherit
from PlatformRemoteDarwinDevice and all the functionality it provides,
such as looking at the correct DeviceSupport directory.
rdar://68167374
Differential revision: https://reviews.llvm.org/D92452
We currently reject all templates that have either zero args or that have a
parameter pack without a name. Both cases are actually allowed in C++, so
rejecting them leads to LLDB instead falling back to a dummy 'void' type. This
leads to all kind of errors later on (most notable, variables that have such
template types appear to be missing as we can't have 'void' variables and
inheriting from such a template type will cause Clang to hit some asserts when
finding that the base class is 'void').
This just removes the too strict tests and adds a few tests for this stuff (+
some combinations of these tests with preceding template parameters).
Things that I left for follow-up patches:
* All the possible interactions with template-template arguments which seem like a whole new source of possible bugs.
* Function templates which completely lack sanity checks.
* Variable templates are not implemented.
* Alias templates are not implemented too.
* The rather strange checks that just make sure that the separate list of
template arg names and values always have the same length. I believe those
ought to be asserts, but my current plan is to move both those things into a
single list that can't end up in this inconsistent state.
Reviewed By: JDevlieghere, shafik
Differential Revision: https://reviews.llvm.org/D92425
This patch carries forward our aim to remove offset field from qRegisterInfo
packets and XML register description. I have created a new function which
returns if offset fields are dynamic meaning client can calculate offset on
its own based on register number sequence and register size. For now this
function only returns true for NativeRegisterContextLinux_arm64 but we can
test this for other architectures and make it standard later.
As a consequence we do not send offset field from lldb-server (arm64 for now)
while other stubs dont have an offset field so it wont effect them for now.
On the client side we have replaced previous offset calculation algorithm
with a new scheme, where we sort all primary registers in increasing
order of remote regnum and then calculate offset incrementally.
This committ also includes a test to verify all of above functionality
on Arm64.
Reviewed By: labath
Differential Revision: https://reviews.llvm.org/D91241
These callbacks are set using the following:
breakpoint command add -s lua -o "print('hello world!')"
The user supplied script is executed as:
function (frame, bp_loc, ...)
<body>
end
So the local variables 'frame', 'bp_loc' and vararg are all accessible.
Any global variables declared will persist in the Lua interpreter.
A user should never hold 'frame' and 'bp_loc' in a global variable as
these userdatas are context dependent.
Differential Revision: https://reviews.llvm.org/D91508
Previously if you did:
$ lldb-server platform --server <...> --min-gdbserver-port 12346
--max-gdbserver-port 12347
(meaning only use port 12346 for gdbservers)
Then tried to launch two gdbservers on the same connection,
the second one would return port 65535. Which is a real port
number but it actually means lldb-server didn't find one it was
allowed to use.
send packet: $qLaunchGDBServer;<...>
read packet: $pid:1919;port:12346;#c0
<...>
send packet: $qLaunchGDBServer;<...>
read packet: $pid:1927;port:65535;#c7
This situation should be an error even if port 65535 does happen
to be available on the current machine.
To fix this make PortMap it's own class within
GDBRemoteCommunicationServerPlatform.
This almost the same as the old typedef but for
GetNextAvailablePort() returning an llvm::Expected.
This means we have to handle not finding a port,
by returning an error packet.
Also add unit tests for this new PortMap class.
Reviewed By: labath
Differential Revision: https://reviews.llvm.org/D91634
Translate between abridged and full ftag values in order to expose
the latter in the gdb-remote protocol while the former are used by
FXSAVE/XSAVE... This matches the gdb behavior.
The Shell/Register tests now rely on the new behavior, and therefore
are run on non-Darwin systems only. The Python (API) test relies
on the legacy behavior, and is run on Darwin only.
Differential Revision: https://reviews.llvm.org/D91504
This extends the "memory region" command to
show tagged regions on AArch64 Linux when the MTE
extension is enabled.
(lldb) memory region the_page
[0x0000fffff7ff8000-0x0000fffff7ff9000) rw-
memory tagging: enabled
This is done by adding an optional "flags" field to
the qMemoryRegion packet. The only supported flag is
"mt" but this can be extended.
This "mt" flag is read from /proc/{pid}/smaps on Linux,
other platforms will leave out the "flags" field.
Where this "mt" flag is received "memory region" will
show that it is enabled. If it is not or the target
doesn't support memory tagging, the line is not shown.
(since majority of the time tagging will not be enabled)
Testing is added for the existing /proc/{pid}/maps
parsing and the new smaps parsing.
Minidump parsing has been updated where needed,
though it only uses maps not smaps.
Target specific tests can be run with QEMU and I have
added MTE flags to the existing helper scripts.
Reviewed By: labath
Differential Revision: https://reviews.llvm.org/D87442
Translate between abridged and full ftag values in order to expose
the latter in the gdb-remote protocol while the former are used by
FXSAVE/XSAVE... This matches the gdb behavior.
Differential Revision: https://reviews.llvm.org/D91504
The FXSAVE/XSAVE data can have two different layouts on x86_64. When
called as FXSAVE/XSAVE..., the Instruction Pointer and Address Pointer
registers are reported using a 16-bit segment identifier and a 32-bit
offset. When called as FXSAVE64/XSAVE64..., they are reported using
a complete 64-bit offsets instead.
LLDB has historically followed GDB and unconditionally used to assume
the 32-bit layout, with the slight modification of possibly
using a 32-bit segment register (i.e. extending the register into
the reserved 16 upper bits). When the underlying operating system used
FXSAVE64/XSAVE64..., the pointer was split into two halves,
with the upper half repored as the segment registers. While
reconstructing the full address was possible on the user end (and e.g.
the FPU register tests did that), it certainly was not the most
convenient option.
Introduce a two additional 'fip' and 'fdp' registers that overlap
with 'fiseg'/'fioff' and 'foseg'/'foff' respectively, and report
the complete 64-bit address.
Differential Revision: https://reviews.llvm.org/D91497
Use offset-based method to access x86 debug registers. This also
involves adding a test for the correctness of these offsets, and making
GetDR() method of NativeRegisterContextWatchpoint_x86 public to avoid
duplicate code.
Differential Revision: https://reviews.llvm.org/D91268
Use offset-based method to access base x87 FPU registers, using offsets
relative to the position of 'struct FPR', as determined by the location
of first register in it (fctrl). Change m_fpr to use a fixed-size array
matching FXSAVE size (512 bytes). Add unit tests for verifying
RegisterInfo offsets and sizes against the FXSAVE layout.
Differential Revision: https://reviews.llvm.org/D91248
Read and write registers from m_gpr using offsets from RegisterInfo
rather than explicit switch-case. This eliminates a lot of redundant
code, and avoids mistakes such as type mismatches seen recently (wrt
segment registers). The same logic will be extended to other register
sets in the future.
Make m_gpr an uint8_t std::array to ease accesses. Ideally, we could
avoid including <machine/reg.h> entirely in the future and instead
get the correct GPR size from Utility/RegisterContextFreeBSD_* somehow.
While at it, modify register set logic to use an explicit enum with
llvm::Optional<>, making the code cleaner and at the same time enabling
compiler warnings for unhandled sets.
Since now we're fully relying on 'struct GPR' defined
in Utility/RegisterContextFreeBSD_* being entirely in sync with
the system structure, add unit tests to verify the field offsets
and sizes.
Differential Revision: https://reviews.llvm.org/D91216
Buildbot failed on Windows
http://lab.llvm.org:8011/#/builders/83/builds/693
Error: On Windows, std::future can't hold an Expected, as it doesn't have a default
constructor.
Solution: Use std::future<bool> instead of std::future<Expected<T>>
Depends on D89283.
The goal of this packet (jTraceGetSupportedType) is to be able to query the gdb-server for the tracing technology that can work for the current debuggeer, which can make the user experience simpler but allowing the user to simply type
thread trace start
to start tracing the current thread without even telling the debugger to use "intel-pt", for example. Similarly, `thread trace start [args...]` would accept args beloging to the working trace type.
Also, if the user typed
help thread trace start
We could directly show the help information of the trace type that is supported for the target, or mention instead that no tracing is supported, if that's the case.
I added some simple tests, besides, when I ran this on my machine with intel-pt support, I got
$ process plugin packet send "jTraceSupportedType"
packet: jTraceSupportedType
response: {"description":"Intel Processor Trace","pluginName":"intel-pt"}
On a machine without intel-pt support, I got
$ process plugin packet send "jTraceSupportedType"
packet: jTraceSupportedType
response: E00;
Reviewed By: clayborg, labath
Differential Revision: https://reviews.llvm.org/D90490
Dwarf says (Section 2.5.1.1. of DWARF v5) that these operations should
push "generic" (pointer-sized) values. This was not the case for
DW_OP_const operations (which were pushing values based on the size of
arguments), nor DW_OP_litN (which were always pushing 64-bit values).
The practical effect of this that were were unable to display the values
of variables if the size of the DW_OP_const opcode was smaller than the
value of the variable it was describing. This would happen because we
would store this (small) result into a buffer and then would not be able
to read sufficient data out of it (in Value::GetValueAsData). Gcc emits
debug info like this.
Other (more subtle) effects are also possible.
The same fix should be applied to DW_OP_const[us] (leb128 versions), but
I'm not doing that right now, because that would cause us to display
wrong (truncated) values of variables on 32-bit targets (pr48087).
Differential Revision: https://reviews.llvm.org/D90840
The class only supports a single DWARF unit (needed for my new test), and it
reimplements chunks of object and symbol file classes. We can just make it use
the real thing, save some LOC and get the full feature set.
Differential Revision: https://reviews.llvm.org/D90393
This patch completes https://reviews.llvm.org/D83560. Now that the
compiler can emit `DW_OP_implicit_value` into DWARF expressions, lldb
needed to learn reading these opcodes for variable inspection and
expression evaluation.
This implicit location descriptor specifies an immediate value with two
operands: the length (ULEB128) followed by a block representing the value
in the target memory representation.
rdar://67406091
Differential revision: https://reviews.llvm.org/D89842
Signed-off-by: Med Ismail Bennani <medismail.bennani@gmail.com>
This patch adds support for the _M and _m gdb-remote packets, which
(de)allocate memory in the inferior. This works by "injecting" a
m(un)map syscall into the inferior. This consists of:
- finding an executable page of memory
- writing the syscall opcode to it
- setting up registers according to the os syscall convention
- single stepping over the syscall
The advantage of this approach over calling the mmap function is that
this works even in case the mmap function is buggy or unavailable. The
disadvantage is it is more platform-dependent, which is why this patch
only works on X86 (_32 and _64) right now. Adding support for other
linux architectures should be easy and consist of defining the
appropriate syscall constants. Adding support for other OSes depends on
the its ability to do a similar trick.
Differential Revision: https://reviews.llvm.org/D89124
This is essentially a replacement for the PacketUnimplementedError
previously present in the gdb-remote server code.
The reason I am introducing a generic error is because I wanted the
native process classes to be able to signal that they do not support
some functionality. They could not use PacketUnimplementedError as they
are independent of a specific transport protocol. Putting the error
class in the the native process code was also not ideal because the
gdb-remote code is also used for lldb-server's platform mode, which does
not (should not) know how to debug individual processes.
I'm putting it under Utility, as I think it can be generally useful for
notifying about unsupported/unimplemented functionality (and in
particular, for programatically testing whether something is
unsupported).
Differential Revision: https://reviews.llvm.org/D89121
This patch fixes a few issues seen when running `ninja check-lldb` in a Release build with VS2017:
- Some binaries couldn't be found (such as lldb-vscode.exe), because .exe wasn't appended to the file name.
- Many tests used to fail since our installed locale is in French - the OS error messages are not emitted in English.
- Our codepage being Windows-1252, python failed to decode some error messages with accentuations.
Differential Revision: https://reviews.llvm.org/D88975
When running in an ipv6-only environment where `AF_INET` sockets are not available, many lldb tests (mostly gdb remote tests) fail because things like `127.0.0.1` don't work there.
Use `localhost` instead of `127.0.0.1` whenever possible, or include a fallback of creating `AF_INET6` sockets when `AF_INET` fails.
Reviewed By: labath
Differential Revision: https://reviews.llvm.org/D87333
This reverts commit f775fe5964.
I fixed a return type error in the original patch that was causing a test failure.
Also added a REQUIRES: python to the shell test so we'll skip this for
people who build lldb w/o Python.
Also added another test for the error printing.